The Azimuth Project
The Double-Cylindrical PointFocus (Rev #2, changes)

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The Double-Cylindrical PointFocus

The idea that nobody has wanted - so far

The parabola has the well-known property of reflecting axis-parallel rays to a point, as can be seen in this video clip. If we rotate the parabola around its axis, we create a parabolic disc. It has the well-known property of reflecting parallel rays (= planar wave fronts) to a point - if they are incident along the axis direction of the disc - which can be seen in this video clip.

Now, it is a beautiful (and little known) geometrical fact of great practical consequence that we can avoid the astronomical costs associated with creating a large parabolic disc, and harness the work-power of the sun in a more effective and efficient way by bending two flat mirror sheets into the shape of two parabolic cylinders. If these parabolic cylinders are properly configured, the incoming parallel light rays (= planar wave fronts) will create an exact point focus after two successive reflections. This is due to the

Double Cylindrical Point Focus Principle:

If the focal line of the first cylinder is identical to the generating line of the parabola that is the intersection of the second cylinder with a plane perpendicular to its axis, then the incoming rays will be reflected to a perfect point.

The DCPF principle was discovered on 16 November 1976 by Ambjörn Naeve while working with Lloyd Cross at the Multiplex company in San Francisco, California, and the original insight was recorded on this piece of paper. A geometric proof of the DCPF principle can be found here. Between 9-12 December 1976, Lloyd Cross and Ambjörn Naeve built the first point-focusing mirrors based on the DCPF principle. A short description of this event, including some pictures, can be found here.

A computer-based animation of the double-cylindrical point-focusing mirrors in action action, can created be by seen Ambjörn in Naeve this using theGraphing Calculator, can be seen in this video clip , and a live “burning demo” with a DCPF mirror-pair mirror-pair, can built be by seen in thisTomas Elofsson in 1989, can be seen in this video clip.

In On 1 July 1989, in Gusum, Gusum Sweden, the DCPF mirror-pair shown in this the latter video clip (1.5 m^2 primary mirror) was used in an experiment by Ambjörn Naeve and Tomas Elofsson that melted succeeded in melting limestone (2560 ˚C) in free air. In the pictures below, Tomas Elofsson is shown tuning the mirrors and melting the limestone sample:

Tuning the primary mirror
Tuning the secondary mirror
Melting the limestone sample

A collection of video clips on the double-cylindrical point focus

The DC pointfocus videos by MathRehab on YouTube

Four major advantages of the double-cylindrical point focus

in comparison with the classical parabolic disc point focus

1) It is easier to build in large sizes, since cylindrical surfaces are curved in only one direction and therefore can be BENT into shape from a flat sheet, hence avoiding the “astronomical costs” that occur when a doubly-curved mirror has to be CAST into a fixed shape.

2) The focal point can be positioned outside of the solar influx area between the mirrors, where it is freely available to perform work, as in the DCPF wheelbarrel design.

3) The focal point can be moved by rotating the second cylinder around the focal line of the first cylinder. This fact can be used to create various forms of solid-state heat engines, for example by successively heating and cooling a series of bi-metal coils.

4) The mirror configuration can be approximated with planar strips, the number of which grows LINEARLY with the overall size of the construction – as opposed to the parabolic disc, where the number of planar approximators grows QUADRATICALLY with construction size.

Possible applications of the double-cylindrical point focus

As has been demonstrated above, the DCPF provides a cheap and efficient way to create “a huge burning glass”, which can achieve very high temperatures. Therefore, it enables local (= rural) development of a multitude of technologies that presently require advanced and expensive high-tech labs, such as:

Solar-powered steel plants that recycle scrap metal into a valuable resource for the local community. A discussion and some designs of what a solar steel plant could look like can be found here.

• Cheap and efficient super-heated external combustion engines (steam, sterling, …), whose work-power (like that of all heat engines) increase is with directly proportional to the temperature-difference difference (in ˚K) between input and output. output temperatures.

• Highly efficient solar electricity generators, which concentrate the energy on high-performance photo-voltaic cells that must be water-cooled to avoid melting.

The idea that nobody wanted (1976-2001)

The story of trying to get people interested in the double-cylindrical point focus - from its discovery in 1976 and up until 2001 - can be found here.